Abstract
Mitochondria are believed to play an important role in shaping the intracellular Ca2+ transients during skeletal muscle contraction. There is discussion about whether mitochondrial matrix Ca2+ dynamics always mirror the cytoplasmic changes and whether this happens in vivo in whole organisms. In this study, we characterized cytosolic and mitochondrial Ca2+ signals during spontaneous skeletal muscle contractions in zebrafish embryos expressing bioluminescent GFP-aequorin (GA, cytoplasm) and mitoGFP-aequorin (mitoGA, trapped in the mitochondrial matrix). The Ca2+ transients measured with GA and mitoGA reflected contractions of the trunk observed by transmitted light. The mitochondrial uncoupler FCCP and the inhibitor of the mitochondrial calcium uniporter (MCU), DS16570511, abolished mitochondrial Ca2+ transients whereas they increased the frequency of cytosolic Ca2+ transients and muscle contractions, confirming the subcellular localization of mitoGA. Mitochondrial Ca2+ dynamics were also determined with mitoGA and were found to follow closely cytoplasmic changes, with a slower decay. Cytoplasmic Ca2+ kinetics and propagation along the trunk and tail were characterized with GA and with the genetically encoded fluorescent Ca2+ indicator, Twitch-4. Although fluorescence provided a better spatio-temporal resolution, GA was able to resolve the same kinetic parameters while allowing continuous measurements for hours.
Highlights
In skeletal muscle, calcium ions (Ca2+) released from the sarcoplasmic reticulum bind to troponinC and trigger acto-myosin crossbridge formation and force generation
As these biosensors carry a fluorescent protein (GFP) in addition to the Ca2+-sensing aequorin, their expression and subcellular location was verified by fluorescence microscopy
Aequorin has been used in the study of Ca2+ signaling in developing zebrafish and has contributed to elucidate many embryonic processes [22,30,31,32,33,34,35,36]
Summary
C and trigger acto-myosin crossbridge formation and force generation They can be taken up by the mitochondrial Ca2+ uniporter (MCU) [1,2,3], owing to the inner membrane potential difference [4]. Increased ATP utilization lowers the ATP/ADP ratio, enhancing the rate of the respiratory chain (respiratory control). This functional interdependence between sarcoplasmic reticulum (SR) and mitochondria has a structural support, by the attachment of mitochondria to the Ca2+-release units in the SR [6,7]. Only a few reports have demonstrated this in situ in living organisms [8,10,11]
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